Abstract
THE substances responsible for the red-brown colours of the atmosphere of Jupiter are the source of much debate. Initially it was suggested that the coloured materials are HCN oligomers and polymeric organic nitriles which are formed during electrical storms on Jupiter1,2. This model has been criticised on two grounds: first it seems unlikely that there could be sufficient lightning on Jupiter to account for the intense red-brown coloration and second, the electrical storms could only take place in the lower atmosphere of Jupiter, where condensation of water vapour takes place, and therefore there would have to be some means of transporting the compounds above the NH3 ice clouds3. Another postulate is that the colour comes from elemental sulphur and polysulphides formed by the photolysis of H2S (ref. 4). Organic compounds may also be produced when H2S is photolysed in the presence of CH4 and the other hydrocarbons present in the Jovian atmosphere5,6. Since neither H2S nor NH4SH has been detected in the upper atmosphere of Jupiter it is necessary to postulate either that the rate of H2S photolysis is much faster than its rate of transport to the upper atmosphere, or that sunlight reaches the lower atmosphere through gaps in the ammonia ice clouds and the sulphur and polysulphides so formed are then transported to the upper atmosphere. A third postulate suggests that both organic compounds and polysulphides may be formed by a bombardment of the atmosphere with high energy protons and electrons7.
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References
Chada, M. S., Flores, J. J., Lawless, J. G., and Ponnamperuma, C., Icarus, 15, 39–44 (1971).
Woeller, F., and Ponnamperuma, C., Icarus, 10, 389–392 (1969).
Lewis, J. S., College Park Colloquia on Chemical Evolution, October 23, 1974.
Lewis, J. S., and Prinn, R. N., Science, 169, 472–473 (1970).
Khare, B. N., and Sagan, C., Science, 189, 722–723 (1975).
Sagan, C., and Khare, B. N., Astrophys. J., 168, 563–569 (1971).
Scattergood, T., Lesser, P., and Owen, T., Icarus, 24, 465–471 (1975).
Nicodem, D. E., and Ferris, J. P., Icarus, 19, 495–498 (1973).
Ferris, J. P., and Chen, C. T., J. Am. chem. Soc., 97, 2962–2967 (1975).
Bark, L. S., and Higson, H. G., Talanta, 11, 621–631 (1964).
Kruse, J. M., and Mellon, M. J., Analyt. Chem., 25, 446–450 (1953) as modified by Chen, C. T., thesis Univ. Boston, 38–39 (1973).
Watt, G. W., and Crisp, J. D., Analyt. Chem., 24, 2006–2008 (1952).
Sagan, C., and Khare, B. N., Science, 173, 417–420 (1971).
Hong, K.-Y., Hong, J.-H., and Becker, R. S., Science, 184, 984–987 (1974).
Becker, R. S., Hong, K.-Y., and Hong, J.-H., J. molec. Evol., 4, 157–172 (1974).
Ridgway, S. T., Astrophys. J. Lett., 187, L41–L43 (1974).
Ferris, J. P., and Nicodem, D. E., Nature, 238, 268–269 (1972).
Ferris, J. P., and Nicodem, D. E., The Origin of Life and Evolutionary Biochemistry (edit. by Dose, K., Fox, S. W., Deborin, Q. A., and Pavlovskaya, T. E.), 107–117 (Plenum, New York, 1974).
Ferris, J. P., Williams, E. A., Nicodem, D. E., Hubbard, J. S., and Voecks, G. E., Nature, 249, 437–439 (1974).
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FERRIS, J., CHEN, C. Photosynthesis of organic compounds in the atmosphere of Jupiter. Nature 258, 587–588 (1975). https://doi.org/10.1038/258587a0
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DOI: https://doi.org/10.1038/258587a0
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